English

Optimal shrinkage-based portfolio selection in high dimensions

Statistical Finance 2023-04-19 v5 Statistics Theory Portfolio Management Statistics Theory

Abstract

In this paper we estimate the mean-variance portfolio in the high-dimensional case using the recent results from the theory of random matrices. We construct a linear shrinkage estimator which is distribution-free and is optimal in the sense of maximizing with probability 11 the asymptotic out-of-sample expected utility, i.e., mean-variance objective function for different values of risk aversion coefficient which in particular leads to the maximization of the out-of-sample expected utility and to the minimization of the out-of-sample variance. One of the main features of our estimator is the inclusion of the estimation risk related to the sample mean vector into the high-dimensional portfolio optimization. The asymptotic properties of the new estimator are investigated when the number of assets pp and the sample size nn tend simultaneously to infinity such that p/nc(0,+)p/n \rightarrow c\in (0,+\infty). The results are obtained under weak assumptions imposed on the distribution of the asset returns, namely the existence of the 4+ε4+\varepsilon moments is only required. Thereafter we perform numerical and empirical studies where the small- and large-sample behavior of the derived estimator is investigated. The suggested estimator shows significant improvements over the existent approaches including the nonlinear shrinkage estimator and the three-fund portfolio rule, especially when the portfolio dimension is larger than the sample size. Moreover, it is robust to deviations from normality.

Keywords

Cite

@article{arxiv.1611.01958,
  title  = {Optimal shrinkage-based portfolio selection in high dimensions},
  author = {Taras Bodnar and Yarema Okhrin and Nestor Parolya},
  journal= {arXiv preprint arXiv:1611.01958},
  year   = {2023}
}

Comments

45 pages, UPDATE3: revised version of the manuscript accepted by Journal of Business and Economic Statistics. substantially revised: Ledoit-Wolf and Kan-Zhou estimators were added, conditions weakened, proofs revised, discussion on the Moore-Penrose approximation included, mistake in the shrinkage formula for c>1 corrected (big boost in performance as a result)

R2 v1 2026-06-22T16:43:54.720Z